The present invention relates to refrigeration control systems, and more particularly to integrated control and monitoring of refrigeration system compressors.
Refrigeration systems typically include a compressor, a condenser, an expansion valve, and an evaporator, all interconnected to form a fluid circuit. Cooling is accomplished through evaporation of a liquid refrigerant under reduced temperature and pressure. Vapor refrigerant is compressed to increase its temperature and pressure. The vapor refrigerant is condensed in the condenser, lowering its temperature to induce a state change from vapor to liquid.
The pressure of the liquid refrigerant is reduced through an expansion valve and the liquid refrigerant flows into the evaporator. The evaporator is in heat exchange relationship with a cooled area (e.g., an interior of a refrigeration case). Heat is transferred from the cooled area to the liquid refrigerant inducing a temperature increase sufficient to result in vaporization of the liquid refrigerant. The vapor refrigerant then flows from the evaporator to the compressor.
The refrigeration system can include multiple evaporators such as in the case of multiple refrigeration cases and multiple compressors connected in parallel in a compressor rack. The multiple compressors can be controlled individually or as a group to provide a desired suction pressure for the refrigeration system.
A system controller monitors and regulates operation of the refrigeration system based on control algorithms and inputs relating to the various system components. Such inputs include, but are not limited to, the number of compressors operating in the refrigeration system and the details of individual compressors, including compressor capacity and setpoints. During initial assembly of the refrigeration system, these inputs must be manually entered into the memory of the refrigeration controller. If a compressor is replaced, the inputs for the removed compressor must be manually erased from the memory and new inputs for the replacement compressor manually entered into the memory. Such manual entry of the inputs is time consuming and prone to human error.
Accordingly, the present invention provides a refrigeration system includes a refrigeration component and an electronics module that is attached to the refrigeration component. The electronics module stores a data set including identification and configuration parameters of the refrigeration component. A refrigeration system controller communicates with the electronics module to obtain the data set and to regulate operation of the refrigeration component within the refrigeration system.
In one feature, the refrigeration component is operable in a normal operating state and is inoperable in a lock-out state. The refrigeration system controller monitors occurrences of the refrigeration component in the lock-out state.
In still another feature, the refrigeration component communicates initial configuration information to the refrigeration system controller upon assembly of the refrigeration component into the refrigeration system. The initial information includes operating parameters and component identity.
In yet another feature, the refrigeration component is a compressor. The controller regulates compressor capacity based on rated compressor capacity and current operating conditions of the compressor. The operating conditions include suction pressure, suction temperature, discharge pressure and discharge temperature.
Further areas of applicability of the present invention will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.
The present invention will become more fully understood from the detailed description and the accompanying drawings, wherein:
The following description of the preferred embodiments is merely exemplary in nature and is in no way intended to limit the invention, its application, or uses.
Referring now to
As shown, the refrigeration system 100 includes a plurality of compressors 102 piped together with a common suction manifold 106 and a discharge header 108 all positioned within a compressor rack 110. A discharge output 112 of each compressor 102 includes a respective temperature sensor 114. An input 116 to the suction manifold 106 includes both a pressure sensor 118 and a temperature sensor 120. Further, a discharge outlet 122 of the discharge header 108 includes an associated pressure sensor 124.
The compressor rack 110 compresses refrigerant vapor that is delivered to a condenser 126 where the refrigerant vapor is liquefied at high pressure. The condenser 126 includes an associated ambient temperature sensor 128 and an outlet pressure sensor 130. This high-pressure liquid refrigerant is delivered to a plurality of refrigeration cases 131 by way of piping 132. Each refrigeration case 131 is arranged in separate circuits optionally including multiple refrigeration cases 131 that operate within a certain temperature range.
Because the temperature requirement is different for each circuit, each circuit includes a pressure regulator 134 that acts to control the evaporator pressure and, hence, the temperature of the refrigerated space in the refrigeration cases 131. The pressure regulators 134 can be electronically or mechanically controlled. Each refrigeration case 131 also includes its own evaporator 136 and its own expansion valve 138 that may be either a mechanical or an electronic valve for controlling the superheat of the refrigerant. In this regard, refrigerant is delivered by piping to the evaporator 136 in each refrigeration case 131. The refrigerant passes through the expansion valve 138 where a pressure drop causes the high pressure liquid refrigerant to achieve a lower pressure combination of liquid and vapor. As hot air from the refrigeration case 131 moves across the evaporator 136 and cools the refrigerated space, the low pressure liquid turns into gas. This low pressure gas is delivered to the pressure regulator 134 associated with that particular circuit. At the pressure regulator 134, the pressure is dropped as the gas returns to the compressor rack 110. At the compressor rack 110, the low pressure gas is again compressed to a high pressure gas, which is delivered to the condenser 126. The condenser 126 provides a high pressure liquid that flows to the expansion valve 138, starting the refrigeration cycle again.
A main refrigeration controller 140 is used and configured or programmed to control the operation of the refrigeration system 100. The refrigeration controller 140 is preferably an Einstein Area Controller such as an Einstein 2 (E2) controller offered by CPC, Inc. of Atlanta, Ga., U.S.A., or any other type of programmable controller that may be programmed, as discussed herein. The refrigeration controller 140 controls the bank of compressors 104 in the compressor rack 110, via an electronics module 160, which may include relay switches to turn the compressors 102 on and off to provide the desired suction pressure. A case controller 142, such as a CC-100 case controller, also offered by CPC, Inc. of Atlanta, Ga., U.S.A., may be used to control the superheat of the refrigerant to each refrigeration case 131, via an electronic expansion valve in each refrigeration case 131 by way of a communication network or bus 152. Alternatively, a mechanical expansion valve may be used in place of the separate case controller. Should separate case controllers be utilized, the main refrigeration controller 140 may be used to configure each separate case controller, also via the communication bus 152. The communication bus 152 may operate using any communication protocol, e.g., an RS-485 communication bus or a LonWorks Echelon bus, that enables the main refrigeration controller 140 and the separate case controllers to receive information from each refrigeration case 131.
Each refrigeration case 131 may have a temperature sensor 146 associated therewith, as shown for circuit B. The temperature sensor 146 can be electronically or wirelessly connected to the controller 140 or the expansion valve for the refrigeration case 131. Each refrigeration case 131 in the circuit B may have a separate temperature sensor 146 to take average/minimum/maximum temperatures or a single temperature sensor 146 in one refrigeration case 131 within circuit B may be used to control each refrigeration case 131 in circuit B because all of the refrigeration cases 131 in a given circuit generally operate within a similar temperature range. These temperature inputs are provided to the main refrigeration controller 140 via the communication bus 152.
Additionally, further sensors can be provided and correspond with each component of the refrigeration system 100 and are in communication with the refrigeration controller 140. Energy sensors 150 are associated with the compressors 104 and condenser 126 of the refrigeration system 100. The energy sensors 150 monitor energy consumption of their respective components and communicate that information to the refrigeration controller 140.
The refrigeration controller 140 is configured to control and monitor system components such as suction groups, condensers, standard circuits, analog sensors, and digital sensors. The systems are monitored real-time. For suction groups, setpoints, status, capacity percentages, and stage activity for each suction group are displayed by an output of the refrigeration controller 140, such as a display screen 154. For circuits, circuit names, current status, and temperatures are displayed. For condensers, information on discharge setpoint and individual fan states is provided. The refrigeration controller 140 also includes a data table with default operating parameters for most commercially available refrigeration case types. By selecting a known case type, the refrigeration controller 140 automatically configures the default operating parameters, such as the setpoint, the number of defrosts per day and defrost time for the particular case type.
The compressors 102 include the embedded intelligence boards or electronics modules 160 that communicate compressor and system data to the refrigeration controller 140, as explained in further detail herein. Traditional I/O boards are replaced by the electronics modules 160, which communicate with the refrigeration controller 140. More specifically, the electronics modules 160 perform the I/O functions. The refrigeration controller 140 sends messages to the individual electronics modules 160 to provide control (e.g., compressor ON/OFF or unloader ON/OFF) and receives messages from the electronics modules 160 concerning the status of the electronics module 160 and the corresponding compressor 102.
The refrigeration controller 140 monitors the operating conditions of the compressors 102 including discharge temperature, discharge pressure, suction pressure and suction temperature. The compressor operating conditions influence the capacity of the individual compressors 102. The refrigeration controller 140 calculates the capacity of each compressor 102 using a compressor model based on the compressor Air-Conditioning and Refrigeration Institute (ARI) coefficients, discharge temperature, discharge pressure, suction pressure and suction temperature. The calculated capacities are then processed through a suction pressure algorithm to determine which compressors 102 to switch on/off to achieve the desired suction pressure.
Exemplary data received by the refrigeration controller 140 includes the number of compressors 102 in the refrigeration system 100, horsepower of each compressor, method of oil control/monitoring of the compressors, method of proofing the compressors 102 and the I/O points in the refrigeration controller 140 used to control the compressors 102. Much of the data is resident in the electronics module 160 of each of the compressors 102, as described in detail below and is therefore specific to that compressor. Other data is mined by the refrigeration controller 140 and is assembled in a controller database. In this manner, the refrigeration system 140 communicates with the individual electronics modules 160 to automatically populate the controller database and provide an initial system configuration. As a result, time consuming, manual input of these parameters is avoided.
The electronics module 160 of the individual compressors 102 further includes compressor identification information, such as the model and serial numbers of the associated compressor 102, which is communicated to the refrigeration controller 140. The compressor identification information is described in further detail below. The refrigeration controller 140 populates an asset management database 162 that is resident on a remote computer or server 164. The refrigeration controller 140 communicates with remote computer/server 164 to automatically populate the asset management database 162 with information provided by the electronics module 160. In this manner, the asset management database 162 is continuously updated and the status of each component of the refrigeration system 100 is readily obtainable.
The compressor data from the electronics module 160 includes compressor identification information and compressor configuration information. The compressor identification information and the compressor configuration information includes, but is not limited to, the information respectively listed in Table 1 and Table 2, below:
The compressor data is preconfigured during manufacture (i.e., factory settings) and is retrieved by the refrigeration system controller 140 upon initial connection of the compressor 102 and its corresponding electronics module. The compressor data can be updated with application-specific settings by the refrigeration system controller or by a technician using the refrigeration system controller 140. The updated compressor data is sent back to and is stored in the electronics module 160. In this manner, the preconfigured compressor data can be updated based on the requirements of the specific refrigeration system 100.
The refrigeration controller 140 monitors the compressors 102 for alarm conditions and maintenance activities. One such example is monitoring for compressor oil failure, as described in further detail below. Because the refrigeration controller 140 stores operating history data, it can provide a failure and/or maintenance history for the individual compressors 102 by model and serial number.
The refrigeration controller 140 is responsible for addressing and providing certain configuration information for the electronics modules 160. This occurs during first power up of the refrigeration system (i.e., finding all electronics modules 160 in the network and providing appropriate address and configuration information for the electronics modules 160), when a previously addressed and configured electronics module 160 is replaced by a new electronics module 160 and when an electronics module 160 is added to the network. During each of these scenarios, the refrigeration controller 140 provides a mapping screen that lists the serial numbers of the electronics modules 160 that are found. The screen will also list the name of each electronics module 160 and the firmware revision information.
In general, a technician who replaces or adds an electronics module 160 is required to enter a network setup screen in the refrigeration controller 140 and inform the refrigeration controller 140 that an electronics module 160 has been added or deleted from the network. When an electronics module 160 is replaced, the technician enters the network setup screen for the electronics modules 160 and initiates a node recovery. During the node recovery, existing electronics modules 160 retain their setup information and any links that the technician has established to the corresponding suction groups. The results are displayed on the network setup screen. The technician has the capability to delete the old electronics module 160 from the refrigeration controller 140.
A cell is created in the refrigeration controller 140 to act as an interface to each electronics module 160. The cell contains all inputs, outputs and configuration setpoints that are available on the particular electronics module 160. In addition, the cell contains event information and a text string that represents the current display code on the electronics module 160. The cell data includes status information, configuration information, control data, event data, ID reply data, ID set data and summary data.
The status information is provided in the form of fields, which include, but is not limited to, display code, compressor running, control voltage low, control voltage dropout, controller failure, compressor locked out, welded contactor, remote run available, discharge temperature, model number, serial number, compressor control contact, liquid injection contact and error condition outputs. The control data enables the technician to set the data that is sent to the electronics module 160 for control. The control data includes, but is not limited to, compressor run request, unloader stage 1 and unloader stage 2. The compressor run request controls the run command to the compressor 102. This is typically tied to a compressor stage in the suction group cell.
With regard to event data, the refrigeration controller 140 has the capability to retrieve and display all of the event codes and trip information present on the particular electronics module 160. The cell provides correlation between the event code, a text display representing the code and the trip time. The screen will also display the compressor cycle information (including short cycle count) and operational time. The summary data is provided on a summary screen in the refrigeration controller 140 that lists the most important status information for each electronics module 160 and displays all electronics modules.
Each electronics module 160 can generate a trip event and/or a lockout event. A trip event is generated when an event occurs for a temporary period of time and generally clears itself. An example of a trip occurs when the motor temperature exceeds the a threshold for a period of time. The electronics module 160 generates a motor temperature trip signal and clears the trip when the motor temperature returns to a normal value. A lockout event indicates a condition that is not self clearing (e.g., a single phase lockout).
The refrigeration controller 140 polls the status of each. electronics module 160 on a regular basis. If the electronics module 160 is in a trip condition, the refrigeration controller 140 logs a trip in an alarm log. Trips are set up as notices in the alarm log. If the electronics module 160 is in a lockout condition, the refrigeration controller 140 generates a lockout alarm in the alarm log. The cell has the capability to set priorities for notices and alarms. It is also anticipated that a lockout can be remotely cleared using the refrigeration controller 140.
When a technician either resets or otherwise acknowledges an alarm or notice associated with the electronics module 160, the appropriate reset is sent to the electronics module 160 to clear the trip or lockout condition. The trips include, but are not limited to, low oil pressure warning, motor protection, supply voltage, discharge pressure, phase loss, no three phase power, discharge temperature and suction pressure. The lockouts include, but are not limited to low oil pressure, welded contactor, module failure, discharge temperature, discharge pressure and phase loss.
With particular regard to the low oil pressure lockout, the electronics module 160 communicates the number of oil resets that have been performed to the refrigeration controller 140. If the number of resets exceeds a threshold value, a problem with the refrigeration system 100 may be indicated. The refrigeration controller 140 can send an alarm or initiate maintenance actions based on the number of lockout resets.
The welded contactor lockout provides each electronics module 160 with the ability to sense when a contactor has welded contacts. It does this by monitoring the voltage applied by the contactor based on whether the electronics module 160 is calling for the contactor to be ON or OFF. If a single phase (or 2 phases) are welded in the contactor and the contactor is inadvertently turned off, this condition can lead to compressor damage. It also affects the ability of the suction pressure control algorithm since the refrigeration controller 140 could be calling for the compressor 102 to be OFF, but the compressor continues to run. To mitigate the problems caused by this condition, the suction pressure algorithm in the refrigeration controller 140 is adapted to recognize this condition via the electronics module 160. When a welded contactor condition is detected, the associated compressor 102 is held ON by the suction group algorithm and the appropriate alarm condition is generated, which avoids damage to the compressor motor.
The technician can readily connect an electronics module equipped compressor 102 into a suction group. All pertinent connections between the electronics module 160 and suction group cells are automatically established upon connection of the compressor 102. This includes the type (e.g., compressor or unloader), compressor board/point (i.e., application/cell/output) and proof of board/point. A screen similar to the mapping screen enables the technician to pick which electronics modules 160 belong to a suction group.
It is further anticipated that additional features can be incorporated into the refrigeration system 100. One feature includes an electronics module/refrigeration controller upload/download, which provides the capability to save the parameters from an electronics module 160 to the refrigeration controller 140. If the saved electronics module 160 is replaced, the parameters are downloaded to the new electronics module 160, making it easier to replace an electronics module in the field.
Another feature includes cell data breakout, which provides a discrete cell output for each trip or alarm condition. The cell output would enable these conditions to be connected to other cell's for analysis or other actions. For example, the discharge temperature lockout status from multiple electronics modules 160 could be connected to a super-cell that reviews the status and diagnoses a maintenance action based on how many electronics modules 160 have a discharge temperature trip and the relative timing of the trips.
Still another feature includes an automatic reset of the lockout conditions in the event of a lockout. More specifically, the refrigeration controller 140 automatically attempts a reset of a lockout condition (e.g., an oil failure lockout) when the condition occurs. If the reset attempt repeatedly fails, an alarm would then be generated.
Yet another feature includes phase monitor replacement. More specifically, a phase monitor is traditionally installed in a compressor rack. The electronics modules 160 can be configured to generate a phase monitor signal, removing the need for a separate phase monitor. If all the electronics modules 160 on a given rack signal a phase loss, a phase loss on the rack is indicated and an alarm is generated.
The description of the invention is merely exemplary in nature and, thus, variations that do not depart from the gist of the invention are intended to be within the scope of the invention. Such variations are not to be regarded as a departure from the spirit and scope of the invention.
This application claims the benefit of U.S. Provisional Application No. 60/497,616, filed on Aug. 25, 2003, the disclosure of which is incorporated herein by reference.
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